Deep Learning for Real-time Gravitational Wave Detection and Parameter Estimation with LIGO Data

The recent Nobel-prize-winning detections of gravitational waves from merging black holes and the subsequent detection of the collision of two neutron stars in coincidence with electromagnetic observations have inaugurated a new era of multimessenger astrophysics. To enhance the scope of this emergent science, we proposed the use of deep convolutional neural networks for the detection and characterization of gravitational wave signals in real-time. This method, Deep Filtering, was initially demonstrated using simulated LIGO noise. In this article, we present the extension of Deep Filtering using real data from the first observing run of LIGO, for both detection and parameter estimation of gravitational waves from binary black hole mergers with continuous data streams from multiple LIGO detectors. We show for the first time that machine learning can detect and estimate the true parameters of a real GW event observed by LIGO. Our comparisons show that Deep Filtering is far more computationally efficient than matched-filtering, while retaining similar sensitivity and lower errors, allowing real-time processing of weak time-series signals in non-stationary non-Gaussian noise, with minimal resources, and also enables the detection of new classes of gravitational wave sources that may go unnoticed with existing detection algorithms. This approach is uniquely suited to enable coincident detection campaigns of gravitational waves and their multimessenger counterparts in real-time.

[1]  Daniel George,et al.  ENIGMA: Eccentric, Non-spinning, Inspiral Gaussian-process Merger Approximant for the characterization of eccentric binary black hole mergers , 2017, ArXiv.

[2]  The Ligo Scientific Collaboration,et al.  Observation of Gravitational Waves from a Binary Black Hole Merger , 2016, 1602.03837.

[3]  S. Privitera,et al.  Searching for Gravitational Waves from Compact Binaries with Precessing Spins , 2016, 1603.02444.

[4]  Frans Pretorius,et al.  Numerical Relativity and Astrophysics , 2014, 1405.4840.

[5]  N. S. Philip,et al.  Transient Classification in LIGO data using Difference Boosting Neural Network , 2016, 1609.07259.

[6]  Marco Drago,et al.  Proposed search for the detection of gravitational waves from eccentric binary black holes , 2015, 1511.09240.

[7]  Aggelos K. Katsaggelos,et al.  Deep multi-view models for glitch classification , 2017, 2017 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP).

[8]  Richard O'Shaughnessy,et al.  Resonant-plane locking and spin alignment in stellar-mass black-hole binaries: A diagnostic of compact-binary formation , 2013, 1302.4442.

[9]  Vicky Kalogera,et al.  BLACK HOLE MERGERS AND BLUE STRAGGLERS FROM HIERARCHICAL TRIPLES FORMED IN GLOBULAR CLUSTERS , 2015, 1509.05080.

[10]  Enrico Ramirez-Ruiz,et al.  THE FORMATION OF ECCENTRIC COMPACT BINARY INSPIRALS AND THE ROLE OF GRAVITATIONAL WAVE EMISSION IN BINARY–SINGLE STELLAR ENCOUNTERS , 2013, 1308.2964.

[11]  J. Powell,et al.  Classification methods for noise transients in advanced gravitational-wave detectors II: performance tests on Advanced LIGO data , 2016, 1609.06262.

[12]  Frederic A. Rasio,et al.  Binary Black Hole Mergers from Globular Clusters: Masses, Merger Rates, and the Impact of Stellar Evolution , 2016, 1602.02444.

[13]  Daniel George,et al.  Deep Learning for Real-time Gravitational Wave Detection and Parameter Estimation with Advanced LIGO Data , 2017, ArXiv.

[14]  A. Katsaggelos,et al.  Gravity Spy: integrating advanced LIGO detector characterization, machine learning, and citizen science , 2016, Classical and quantum gravity.

[15]  Michael Boyle,et al.  Effective-one-body model for black-hole binaries with generic mass ratios and spins , 2013, Physical Review D.

[16]  Taghi M. Khoshgoftaar,et al.  Deep learning applications and challenges in big data analytics , 2015, Journal of Big Data.

[17]  The Ligo Scientific Collaboration,et al.  GW151226: Observation of Gravitational Waves from a 22-Solar-Mass Binary Black Hole Coalescence , 2016, 1606.04855.

[18]  Lawrence E. Kidder,et al.  Complete waveform model for compact binaries on eccentric orbits , 2016, 1609.05933.

[19]  Daniel George,et al.  Deep Neural Networks to Enable Real-time Multimessenger Astrophysics , 2016, ArXiv.

[20]  G. Mitselmakher,et al.  Method for detection and reconstruction of gravitational wave transients with networks of advanced detectors , 2015, 1511.05999.

[21]  B. A. Boom,et al.  Binary Black Hole Mergers in the First Advanced LIGO Observing Run , 2016, 1606.04856.

[22]  C. Pankow,et al.  Novel scheme for rapid parallel parameter estimation of gravitational waves from compact binary coalescences , 2015, 1502.04370.

[23]  S. Klimenko,et al.  Advanced LIGO , 2014, 1411.4547.

[24]  R. Lynch,et al.  Classification methods for noise transients in advanced gravitational-wave detectors II: performance tests on Advanced LIGO data , 2015, 1505.01299.

[25]  B. A. Boom,et al.  GW170104: Observation of a 50-Solar-Mass Binary Black Hole Coalescence at Redshift 0.2. , 2017, Physical review letters.

[26]  Bharath Pattabiraman,et al.  Binary Black Hole Mergers from Globular Clusters: Implications for Advanced LIGO. , 2015, Physical review letters.

[27]  E. A. Huerta,et al.  Effect of eccentricity on binary neutron star searches in advanced LIGO , 2013, 1301.1895.

[28]  B. A. Boom,et al.  GW170814: A Three-Detector Observation of Gravitational Waves from a Binary Black Hole Coalescence. , 2017, Physical review letters.

[29]  P. Graff,et al.  Parameter estimation for compact binaries with ground-based gravitational-wave observations using the LALInference software library , 2014, 1409.7215.

[30]  Yoshua Bengio,et al.  Gradient-based learning applied to document recognition , 1998, Proc. IEEE.

[31]  Michael Boyle,et al.  On the accuracy and precision of numerical waveforms: effect of waveform extraction methodology , 2015, 1512.06800.

[32]  B. Owen,et al.  Matched filtering of gravitational waves from inspiraling compact binaries: Computational cost and template placement , 1998, gr-qc/9808076.

[33]  Richard O'Shaughnessy,et al.  Accurate and efficient waveforms for compact binaries on eccentric orbits , 2014, 1408.3406.

[34]  Daniel George,et al.  Glitch Classification and Clustering for LIGO with Deep Transfer Learning , 2017, ArXiv.

[35]  C. Ott,et al.  The Einstein Toolkit: a community computational infrastructure for relativistic astrophysics , 2011, 1111.3344.

[36]  Geoffrey E. Hinton,et al.  Deep Learning , 2015, Nature.

[37]  Vladlen Koltun,et al.  Multi-Scale Context Aggregation by Dilated Convolutions , 2015, ICLR.